Fiber optic jack and connector

ABSTRACT

The present invention provides a fiber optic jack for routing optical signals. In another aspect, the present invention provides a fiber optic connector with accurate alignment that may be used with, among other things, the fiber optic jack.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims the benefit of U.S. provisional patentapplication No. 61/149,568, filed on Feb. 3, 2009, the entire contentsof which are incorporated by reference herein.

BACKGROUND

1. Field of the Invention

The present invention generally relates to apparatuses for opticallyconnecting optical fibers.

2. Related Art

A copper jack is very common and almost universally used in thebroadcast industry to manually route electrical signals through abroadcast studio, mobile studio or other area where electrical signalsneed to be routed. As more and more data is being transmitted usingoptical signals rather than electrical signals there is a need toproduce an optical jack that can be used to route optical signals.

SUMMARY

In one aspect, the present invention provides a fiber optic jack forrouting optical signals.

In another aspect, the present invention provides a fiber opticconnector with accurate alignment that may be used with, among otherthings, a fiber optic jack according to embodiments of the invention.

The above and other aspects and embodiments are described below withreference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated herein and form partof the specification, illustrate various embodiments of the presentinvention and, together with the description, further serve to explainthe principles of the invention and to enable a person skilled in thepertinent art to make and use the invention. In the drawings, likereference numbers indicate identical or functionally similar elements.

FIGS. 1-8 illustrate a fiber optic jack according to embodiments of theinvention.

FIGS. 9-11 illustrate a fiber optic connector according to an embodimentof the invention.

FIG. 12 illustrate a fiber optic connector according to anotherembodiment.

FIGS. 13-14 illustrate a fiber optic connector according to anotherembodiment of the invention.

FIGS. 15-25 further illustrate a fiber optic jack according toembodiments of the invention.

DETAILED DESCRIPTION

Referring now to FIG. 1, FIG. 1 illustrates a fiber optic jack 100according to some embodiments of the invention. In the embodiment shown,jack 100 has four ports (ports 102 a,b and 104 a,b) (e.g., fourconnectors). Two on the front and two on the back. Each port isconfigured to mate with (e.g., receive) a counterpart fiber opticconnector. In the embodiment shown, each port is a female connector formating with a male or hermaphroditic fiber optic connector.

Jack 100 has two modes of operation. A “normal” mode and an “interrupt”mode.

FIG. 2 illustrates jack 100 operating in the normal mode. In the normalmode of operation, a first fiber optic connector 202 a is inserted intorear port 102 a and a second fiber optic connector 202 b is insertedinto rear port 102 b. In this configuration, jack 100 optically connectsconnector 202 a to connector 202 b via, for example, an optical signalreflector 110 (e.g., a prism or other optical signal reflector).Accordingly, the rear ports are the ‘normal’ connection and would beused to connect an input and an output signal that are connectedtogether under normal operation of the system.

For the sake of illustration, we will assume that connector 202 a housesan end of an optical fiber that outputs an optical signal into jack 100.Accordingly, this optical signal is reflected by reflector 110 such thatthe optical signal is injected into connector 202 b. Fiber opticconnectors 202 a and 202 b may be expanded beam connectors.

Referring now to FIG. 3, when it is desirable to gain access to thisoptical signal, a third connector 204 a may be plugged into front port104 a of jack 100 causing the optical signal to be injected intoconnector 204 a. For example, in some embodiments, when connector 204 ais fully inserted into port 104 a an optical path from connector 202 ato connector 204 a is automatically created so that any optical signaloutput from connector 202 a will be received by connector 204 a.Similarly, when a connector 204 b is fully inserted into port 104 b anoptical path from connector 204 b to connector 202 b is automaticallycreated so that any optical signal output from connector 204 b will bereceived by connector 202 b.

This allows insertion of a new signal into the signal path andmonitoring of the signal that is present on the rear of the jack byattaching a connector into the front of the jack. For example, if asignal containing an HDTV picture from a camera is carried by theoptical fiber connected to connector 202 a and this signal is normallyrouted to a studio monitor in another room via connector 202 b and onewanted to observe the HDTV signal, then one could plug patch cordconnector 204 a into port 104 a, thereby diverting the optical signalinto the optical fiber of patch cord connector 204 a. Thus, by placingthe other end of the optical fiber connected to connector 204 a into aportable monitor, the optical signal would be routed to the frontconnector and appear on the portable monitor. At the same time, analternative signal from another camera that is carried by the opticalfiber of connector 204 b could be inserted into the optical fiber ofconnector 202 b by plugging connector 204 b into port 104 b. This is oneexample and there are many other reasons why patching may be desirable.Jack 100 may also be implemented with a monitor channel thus having tworear and three front ports.

Referring back to FIG. 1, jack 100 further includes: a reflector holder105 for holding reflector 100, a jack housing 107, which, in theembodiment shown, includes a jack base 106 for receiving the reflectorholder 105. Jack housing 107 may also include a jack cover (not shown inFIG. 1).

Jack Base 106

In the embodiment shown, jack base 106 contains four alignment means(e.g., grooves). Two rear alignment means 120 a, 120 b and two frontalignment means 121 a, 121 b. Each of the rear alignment means 120accepts an alignment sleeve of a fiber optic connector (see e.g.,alignment sleeve 508 shown in FIG. 9) and aligns the optical axis of thefirst rear connector 202 a with the optical axis of the second rearconnector 202 b, through the prism 110, forming a low loss connectionbetween the two connectors. The front two alignment means 120 arearranged in proximity to the prism base such that inserting a connectorinto a front port (104 a or 104 b) causes the reflector holder 105 andreflector 110 to move out of the optical path between port 102 a and 104a and the optical path between port 102 b and 104 b and cause the frontconnectors to be aligned to the rear connectors forming low lossconnections between the two pairs of connectors. Removing the connectorfrom the front panel will cause the prism and prism base to return totheir previous position, again creating a low loss connection betweenthe two rear connectors. The front and rear alignment means may be aV-groove machined into the base 106, a hole drilled in the base, anumber of raised features inserted or machined into the base, or othermethod of optically aligning the connectors with the reflector and frontand rear connectors.

Reflector 110

In some embodiments, reflector 110 is a prism, mirror or reflectivecoated material that will reflect the optical signal from a connectorattached to one rear alignment to the other rear alignment means.

Reflector Holder 105

The reflector holder 105 holds the reflector 110 and allows thereflector to be moved out of the line of the optical beam and return toa position that is kinematically aligned such that the insertion loss isconsistent between switching operations. The reflector holder 105 alsoallows alignment of the prism to the mechanical references using theoptical axes during manufacture of the jack.

Referring back to FIG. 3, as shown in FIG. 3, when a counterpart fiberoptic connector is inserted into port 104 a or 104 b by at least acertain amount, the insertion of the connector causes reflector holder105 to automatically move reflector 110 so that there is a free opticalpath between ports 102 a and 104 a and between ports 102 b and 204 b.Referring now to FIG. 4, in some embodiments, holder 105 has two slantedsurfaces 401 and 402 that face ports 104 a and 104 b, respectively. Jack100 is configured such that when a connector (e.g., connector 204 a) isinserted into port 104 a or 104 b by at least a certain amount, thefront end 508 (a.k.a., alignment sleeve 508) of the connector 204 acontacts holder 105 at slanted wall 401/402 and, because walls 401/402are slanted, exerts an upward force on holder 105 causing holder 105 toautomatically move upwardly relative to base 106. This feature isfurther shown in FIG. 5, which shows a cross-sectional view of jack 100and connectors 202 a, 204 a. Referring back to FIG. 1, guide pins 130a-c guide holder 105 upward when a member presses against wall 401/402.That is, guide pins 130 a-c prevent holder from moving in the directionsof ports 102 a and 102 b when an object exerts a force in the directionof ports 102 a and 102 b on wall 401 or 402.

Referring now to FIG. 6, FIG. 6 further illustrates holder 105. As shownin FIG. 6, holder 105 has a floor 602 on which reflector 110 rests.Accordingly, when holder 105 moves upwardly due to a force on wall401/402, the holder 105 carries the reflector 110 with it. This causesthe reflector 110 to move such that it no longer receives the optical anoptical signal injected into jack 100 via one of the ports 102 a-104 b.

Referring now to FIG. 7, FIG. 7 further illustrates jack base 106according to some embodiments. In the embodiment shown, base 106includes one or more alignment balls 702 for aligning reflector holder105 in the correct position with respect to jack base 106. In theembodiments where alignment balls 702 are used to align reflector holder105 relative to jack base 106, reflector holder 105 includes one or morecorresponding kinematic features 802 (e.g., a ball shaped indentation802 a, a V shaped groove 802 b, and a planar feature 802 c) (see FIG. 8,which shows a view of the bottom of reflector holder 105) for receivingan alignment ball 702.

As also shown in FIG. 7, jack base 106 may include an alignment magnet710. Magnet 710 exerts a downward force on reflector holder 105 and,thus, serves to pull the reflector holder 105 onto the alignment ballsin the normal position. In the non-normal position (i.e., the interruptposition), the magnet continues to apply some force such that when theconnectors are removed from the front of the jack 100, the holder 105settles back to precisely the same position, realigning the prism 110 inthe loopback configuration. The magnet 710 could easily be replaced withor supplemented by a standard compression spring, inserted between acover (not shown) that covers jack base 106 and the prism holder 105.

If the alignment rods 130 were replaced with rotary hinge mechanism, therotary force would also create a spring force, eliminating the need fora spring or magnet. In the normal condition, the guide rods 130 do nottouch or align the prism, this is done by the alignment balls. Howeverin the interrupt actuated position, there is no need for any accuratealignment. The guide rods serve to loosely align the prism holder 105vertically and ensure that when a connector is inserted into a frontport (104 a, 104 b) the prism holder 105 is moved enough so that theprism does not block the path between port 102 a and 104 a or the pathbetween port 102 b and 104 b. These alignment rods 130 could also beimplemented as a hinge mechanism, secured to a rotary joint on the base106 and guiding the prism holder 105 vertically using a loose rotaryattachment on the prism holder.

Counterpart Fiber Optic Connectors

Referring now to FIG. 9, FIG. 9 is a cross sectional view of a connector204, according to some embodiments. As shown in FIG. 9, connector 204includes: a rear alignment sleeve 902; a lens 904; a lens holder 906; afront alignment sleeve 508; and a housing 910. The lens holder 906 mayinclude a cylindrical tube with a hole in the rear to accept an opticalfiber or ferrule (see e.g., FIG. 12 element 1204) holding an opticalfiber.

The lens holder 906 is configured to contain securely lens 904 and has afront section 1102 b (see FIG. 11, which further shows holder 906) whichis convex spherical with the center of the sphere located approximatelyat the front center of the lens. The lens 904 may be attached to theinside of the holder 906 using epoxy or other retention means such as aretaining ring.

The front alignment sleeve 508 may be a cylindrical shaped tube with aconcave spherical rear section 1002 (see FIG. 10, which further showssleeve 508) that mates with the front section of the lens holder 906.

In use, in some embodiments, a fiber is attached in a ferrule usingstandard epoxy curing and fiber and ferrule polishing techniques tosomeone skilled in the art. The ferrule containing the fiber is insertedinto the rear alignment sleeve 902, thus positioning the tip of thefiber so that it is placed at the focal point of the lens 904,substantially collimating light exiting from the fiber, or allowingcollimated light entering the front of the lens to be focused into thefiber with minimal loss.

This alignment may be done by launching laser light into the fiber atthe opposite end to the ferrule/rear alignment housing end. The launchis done through a 1×2 splitter to allow monitoring of the powerreturning into the fiber. The collimator is positioned in a fixture withthe exit beam perpendicular to a gimbal mounted mirror which reflectsthe light back into the lens, where it is focused and enters the launchfiber. This light passes through the 1×2 fiber optic splitter to bedetected by a power meter. The fiber ferrule located in the rearalignment sleeve is moved in the longitudinal direction to maximize thepower returning into the power meter, thus indicating the point of bestfocus. At the point of best focus, ferrule/rear housing interface isbonded together. This bonding may be by crimping, tightening a screw,epoxied, or any mechanical bonding technique. Epoxy used may be UVcured, heat cured.

The front of the lens holder 906 is spherical and is placed into therear of the front alignment sleeve 508. The interface substantiallyaligns the two axes (i.e., the two axes are coincident), the first beingthe optical axis of the assembly containing the rear alignment sleeve,lens, fiber and ferrule and the second being the mechanical centerlineaxis of the outside diameter of the front section of the front alignmentsleeve. The two axes are aligned by supporting the outside diameter ofthe front section of the front alignment sleeve in a V groove pointingto a reference collimator, autocollimator or other means indicating whenthe optical beam is parallel to the V groove sides. The angle betweenthe front and rear axes are adjusted using micropositioners attached tothe rear housing assembly until the two axes are aligned.

Referring back to FIG. 9, housing 910 houses sleeves 902 and 508, lens904 and lens holder 906. Housing 910 may be a cylindrical shaped tube.More specifically, a rear end portion 931 of housing surrounds a frontportion 941 of sleeve 902. In some embodiments an outer ring 920(a.k.a., release collar 920) surrounds a front end portion 921 ofhousing 910. Also, an inner ring 912 may be housed in the front endportion 921 of housing 910.

Referring now to FIG. 12, FIG. 12 illustrates an embodiment of fiberoptic connector 202. This embodiment is similar to the embodiment ofconnector 204 shown in FIG. 9. Like the embodiment shown in FIG. 9, theembodiment shown in FIG. 12 includes an optical assembly that includes:lens 904; a lens holder 1206 in which the lens is disposed; and anoptical fiber holder 1204 (e.g., a ferrule) attached to an end of anoptical fiber 1299. The optical fiber holder 1204 is configured andpositioned such that light exiting the end 1295 of the optical fiberwill be received by the lens 904. As shown in FIG. 12, light exiting end1295 of fiber 1299 will travel through a channel 1288 of holder 1204.The lens 904 is positioned and configured to collimate light exiting theend of optical fiber holder 1204 and received by the lens 904. Forexample, the tip 1285 of holder 1204 is positioned at the focal point oflens 904. The optical assembly has an optical axis along which thecollimated light will travel. This optical axis is substantiallycoincident with the longitudinal access of channel 1288.

As further shown in FIG. 12, connector 202 includes an elongate hollowalignment sleeve 1208 having a centerline axis (a.k.a., longitudinalaxis) extending from one end 1271 of the sleeve 1208 to the other end1272 of the sleeve 1208. Sleeve 1208 is connected to the opticalassembly so that lens 904 is positioned between the tip 1285 of opticalfiber holder 1204 and end 1271 of alignment sleeve 1208. The centerlineaxis of the alignment sleeve 1208 is coincident with the optical axis ofthe optical assembly so that the collimated light will enter the hollowalignment sleeve at end 1271 and exit the sleeve at end 1272.

As further shown in FIG. 12, optical assembly may be housed in a housing1211. As shown, housing 1211 may include an inner housing tube 1202, afront outer housing tube 1210, and a rear outer housing tube 1292. Asshown, tube 1202 may have threads on an outer surface thereof thatengage with threads formed on an inner surface of tube 1210, and reartube 1292 surrounds a rear portion of tube 1202. Like the connectorshown in FIG. 9, the connector shown in FIG. 12 may include lock ring912, which may be retained in the front portion 1221 of tube 1210. Lockring 912 is designed to engage with a retention groove of a counterpartconnector (e.g., connector 102). A release collar 1220 may be positionedso that it surrounds front portion 1221 and contacts lock ring 912.Release collar 1220 functions to disengage lock ring from the retentiongroove of the counterpart connector.

Referring now to FIG. 13, FIG. 13 illustrates another embodiment offiber optic connector 204. Fiber optic connector 204 shown in FIG. 13 issimilar to connector 204 shown in FIG. 9 and connector 202 shown in FIG.12, but connector 204 shown in FIG. 13 does not include the lock ring912 or release collar 920. For example, in the embodiment shown,connector 204 includes the optical assembly of connector 202 andalignment sleeve 508, and includes a housing 1311 that includes an innerhousing tube 1602, a front outer housing tube 1310, and a rear outerhousing tube 1392. As shown, tube 1602 may have threads on an outersurface thereof that engage with threads formed on an inner surface oftube 1310, and rear tube 1392 surrounds a rear portion of tube 1602.Front outer housing 1310 differs from front outer housing 1210 in thathousing 1310 includes a retention groove 1311 formed in a front portion1321 of housing 1310 for receiving a retention spring of a counterpartconnector (e.g., connector 104).

Referring now to FIG. 14, FIG. 14 further illustrates an embodiment ofalignment sleeve 508. As shown in FIG. 14 a ring 1402 is connected to anend 1471 of the alignment sleeve. Ring 1402 may be integrally connectedto sleeve 508. Ring 1402 and sleeve 508 form a cavity 1404. As shown inFIG. 13, the portion of lens holder 1206 in which lens 904 is disposedis positioned in the cavity 1404. In some embodiments, sleeve 508 has alength between about 1 and 2 inches and its outer diameter rangesbetween about 0.04 and 0.12 inches. In some embodiments, sleeve 1208 isidentical to sleeve 508.

Referring now to FIG. 15, FIG. 15 illustrates jack 100 with alow-profile cover 1502 installed. Low profile cover 1502 functions toenclose the reflector 110, reflector holder 105, and other components ofthe jack 100. In the embodiment shown, cover 1502 also serves as anattachment point for the rear ports 102 and front ports 104, which eachhave a portion that passes through an aperture in a rear end and frontend of the cover, respectively. The cover 1502 may be attached to thejack base 106 by screws and held in place by alignment pins.

Referring now to FIGS. 16 and 17, FIGS. 16 and 17 illustrate that jack100 may further include one or more retention clips 1602. Each retentionclip being positioned adjacent a rear port 102 or front port 104. Eachretention clip is designed to press a front portion of a fiber opticconnector to base 106. For example, when a user mates fiber opticconnector 202 with port 102 a the front alignment sleeve 508,1208 of thefiber optic connector 202 passes through the port and into the jack base106, and the clip 1602 positioned adjacent port 102 a will exert onconnector 202's alignment sleeve 508,1208 a force in the direction ofbase 106 (i.e., a downward force), thereby securing the alignment sleeveand assuring that the alignment sleeve will be aligned correctly withinjack 100.

Referring now to FIG. 18, FIG. 18 shows a side view of an exemplaryretention clip 1602. As shown, a portion 1802 of the retention clipdistal to the point of attachment of clip 1602 to the jack base 106 ispositioned directly above groove 102 a. The retention clips 1602 aresized and positioned such that the distance between portion 1502 and thebottom of the side walls of groove 120 a is slightly less than thediameter of a front alignment sleeve 508, 1208. When a front alignmentsleeve 508, 1208 is inserted into groove 120 a via port 102 a the sleevewill contact the retention clip 1602 and push it upwardly. The retentionclip exerts a corresponding downward force which holds the frontalignment sleeve firmly in place in the groove but still allows for thefiber optic connector to be removed from the port.

Referring now to FIG. 19, FIG. 19 further illustrates jack 100 accordingto some embodiments. In the embodiment shown, the retention clips arestructured with two tabs 1902 a,b at the distal end of the retentionclip 1602. In the embodiment shown, the bottom surface of each tab(i.e., the surface that faces groove 120 a) has protuberance 1911 thatextends in the direction of the groove. Accordingly, it is thisprotuberance 1911 that the alignment sleeve 508, 1208 will contact whenthe alignment sleeve is inserted into the groove 120 a.

Referring now to FIG. 20, FIG. 20 shows a detail view of an embodimentof a rear port 102. This embodiment of a rear port is comprised of aninner attachment cylinder 2002 and an outer shroud 2004. The innerattachment cylinder 2002 is configured to accept the front alignmentsleeve 1208 of connector 202. The inner attachment cylinder 2002 isconfigured with a retention groove 2006 around the circumference of thecylinder which engages with lock ring 912 of connector 202 whenconnector 202 is mated with port 102. FIG. 21 shows a sectional view ofan embodiment of a rear port 102 and a connector 202. This view showsthe connector 202 as it is being inserted into rear port 102. As theconnector 202 is connected to rear port 102, the front alignment sleeve1208 is inserted into the inner attachment cylinder 2002. Lock ring 912is not engaged in retention groove 2006 and the connector slides freelyinto or out of the rear port 102. FIG. 22 shows a sectional view of anembodiment of a rear port 102 and connector 202 with the connector 202fully inserted to the rear port 102. Lock ring 912 is fully engaged inretention groove 2006 firmly holding connector 202 in place on rear port102. A user may de-mate connector 202 from port 102 by gripping outerring 1220 and pulling the connector away from the port. This actioncauses lock ring 912 to disengage from the retention groove.

Referring now to FIG. 23, FIG. 23 shows a detail view of an embodimentof a front port 104. This embodiment of a front port is comprised of anouter shroud 2302 and includes a pass through hole 2304 on the closed,flat end of the port. The outer shroud 2302 has a groove formed in theinner wall of shroud 2302 in which groove a retention spring 1792 isseated. FIG. 24 shows a sectional view of an embodiment of a front port104 and connector 204. This view illustrates the connector 204 as it isbeing mated with front port 104. When the connector 204 is being matedwith front port 104 the front alignment sleeve 508 passes through thepass through hole 2304. FIG. 25 shows a sectional view of an embodimentof a front port 104 and connector 204 with the connector 204 mated withfront port 104. Once the connector 204 is mated with front port 104, theretention spring 1792 engages with groove 1311 of connector 204 andexerts an inward radial force on housing 1310 because the inner diameterof spring 1792 is less than the outer diameter of portion 1321 ofhousing 1310. This force is sufficient to prevent the connector 204 fromaccidentally being demated from front port 104, but still allows thecable to be removed without requiring operating of a release collar orsimilar mechanism.

While various embodiments of the present invention have been describedabove, it should be understood that they have been presented by way ofexample only, and not limitation. Thus, the breadth and scope of thepresent invention should not be limited by any of the above-describedexemplary embodiments.

The invention claimed is:
 1. A fiber optic jack, comprising: a firstport configured to accept insertion of a counterpart fiber opticconnector; a second port configured to accept insertion of a counterpartfiber optic connector; and a third port configured to accept insertionof a counterpart fiber optic connector, wherein the fiber optic jack isconfigured such that, when in a normal mode of operation, there existsan optical path between the first port and the second port such that anoptical beam inserted into the fiber optic jack via a counterpartoptical connecter inserted into the first port will arrive at the secondport substantially unattenuated, but in the normal mode of operation nosuch optical path exists between the first port and the third port, thefiber optic jack is further configured such that, when in an interruptmode of operation, there exists an optical path between the first portand the third port such that an optical beam inserted into the fiberoptic jack via a counterpart optical connecter inserted into the firstport will arrive at the third port substantially unattenuated, but inthe interrupt mode of operation no such optical path exists between thefirst port and the second port, and the fiber optic jack is operable totransition from the normal mode of operation to the interrupt mode ofoperation in response to the insertion of a counterpart fiber opticconnector into the third port.
 2. The fiber optic jack of claim 1,further comprising a reflector moveable between a first position and asecond position, wherein the fiber optic jack operates in the normalmode of operation when the reflector is in the first position and thefiber optic jack operates in the interrupt mode of operation when thereflector is in the second position.
 3. The fiber optic jack of claim 2,further comprising a reflector holder, the reflector holder beingarranged and configured to move the reflector from the first position tothe second position as a result of a user mating a counterpart fiberoptic connector with the third port.
 4. The fiber optic jack of claim 3,further comprising guide means for preventing the reflector holder fromsubstantially moving towards the first port in response to an objectexerting a force on the holder in the direction of the first port. 5.The fiber optic jack of claim 4, wherein the guide means comprises anelongate alignment rod.
 6. The fiber optic jack of claim 5, wherein thereflector holder comprises a kinematic feature in a bottom face of theholder that receives the alignment rod.
 7. The fiber optic jack of claimof 6, further comprising a jack base, the jack base having a floor andthe alignment rod is connected to the floor and extends upwardly fromthe floor.
 8. The fiber optic jack of claim 7, further comprising forcemeans for exerting a force on the holder in the direction of the floorof the jack base.
 9. The fiber optic jack of claim 8, wherein the forcemeans comprises a magnet.
 10. The fiber optic jack of claim 7, furthercomprising holder alignment means fixed to the floor of the jack basefor aligning the reflector holder in a certain position with respect tothe jack base.
 11. The fiber optic jack of claim 10, wherein the holderalignment means comprises an alignment ball, and the bottom face of thereflector holder comprises a hold for receiving the alignment ball. 12.The fiber optic jack of claim 4, further comprising: a jack base havinga top surface and a bottom surface, wherein a bottom surface of thereflector holder faces the top surface of the jack base, and thereflector holder comprises a slanted surface that is positioned betweenthe first port and the third port, the slanted surface is positioned andarranged such that an object moving in a straight line from the thirdport towards the first port would run into the slanted surface and exerton the reflector holder a first force tending to move the reflectorholder perpendicularly away from the jack base and a second forcetending to move the reflector holder towards the first port.
 13. Thefiber optic jack of claim 2, wherein movement of the reflector is notelectronically controlled.
 14. The fiber optic jack of claim 2, whereinmovement of the reflector is manually controlled.
 15. The fiber opticjack of claim 1, further comprising: a reflector holder having a cavityand a floor, the reflector holder being moveable between a firstposition and a second position, wherein the fiber optic jack isconfigured such that the fiber optic jack operates in the normal mode ofoperation when the reflector holder is in the first position and thefiber optic jack operates in the interrupt mode of operation when thereflector holder is in the second position; and a reflector disposed inthe cavity of the holder and resting on the floor of the holder.
 16. Thefiber optic jack of claim 15, wherein the reflector holder furthercomprises a slanted surface that is positioned between the first portand the third port, the slanted surface being positioned and arrangedsuch that an object moving in a straight line from the third porttowards the first port would run into the slanted surface and exert onthe reflector holder a first force tending to move the reflector holderperpendicularly away from a base of the fiber optic jack and a secondforce tending to move the reflector holder towards the first port. 17.The fiber optic jack of claim 1, wherein the reflector is a prism. 18.The fiber optic jack of claim 1, further comprising alignment means foraligning a counterpart optical connecter inserted into the first portwith a counterpart optical connecter inserted into the third port. 19.The fiber optic jack of claim 18, further comprising a jack base,wherein the alignment means comprises a groove or hole formed in thejack base for receiving a counterpart fiber optic connector, the grooveor hole extending in a direction from the first port to the third port.20. The fiber optic jack of claim 19, wherein the alignment meanscomprises the groove and the fiber optic jack further comprisesretention means for contacting and holding down an elongate end portionof a counterpart fiber optic connector in the groove.
 21. The fiberoptic jack of claim 20, wherein the retention means comprises a cliphaving an end portion positioned above the groove.
 22. The fiber opticjack of claim 1, wherein the fiber optic jack does not comprise anycollimating lenses, and the counterpart fiber optic connector comprisesa collimating lens.
 23. The fiber optic jack of claim 1, wherein thefiber optic jack is configured such that the fiber optic jack is notoperable to transition from the interrupt mode to the normal mode whilethe counterpart fiber optic connector is inserted in the third port. 24.The fiber optic jack of claim 1, wherein the fiber optic jack does notcomprise any electrically controllable components.
 25. A fiber opticconnector, comprising: an optical assembly comprising: a lens; a lensholder in which the lens is disposed; and an optical fiber holder forholding an end of an optical fiber, the optical fiber holder beingconfigured and positioned such that light exiting the end of the opticalfiber will be received by the lens, wherein the lens is positioned andconfigured to substantially collimate light exiting an optical fiberheld by the optical fiber holder and received by the lens, and theoptical assembly has an optical axis along which the substantiallycollimated light will travel; and an elongate hollow alignment sleevehaving a centerline axis extending from a rear end of the sleeve to afront end of the sleeve, the sleeve being connected to the assembly sothat the lens is positioned between the optical fiber holder and therear end of the alignment sleeve, wherein the centerline axis of thealignment sleeve is substantially parallel with the optical axis of theoptical assembly so that the substantially collimated light will enterthe hollow alignment sleeve at the rear end and exit the hollowalignment sleeve at the front end, and the alignment sleeve issubstantially undeformable.
 26. The fiber optic connector of claim 25,wherein the elongate hollow alignment sleeve has a concave sphericalrear section for mating with a front section of the lens holder.
 27. Thefiber optic connector of claim 25, further comprising a ring connectedto the rear end of the alignment sleeve, wherein the lens and at least aportion of the lens holder are located within the ring.
 28. The fiberoptic connector of claim 27, wherein the alignment sleeve and ring areintegrally connected.
 29. The fiber optic connector of claim 25, whereinthe optical assembly further comprises an outer sleeve, wherein the ringand the lens holder are housed within the outer sleeve.
 30. The fiberoptic connector of claim 25, wherein the optical fiber holder isintegrally part of the lens holder.
 31. The fiber optic connector ofclaim 25, wherein the optical fiber holder is a ferrule having a firstportion housed within a cavity formed by an end portion of the lensholder and having a second portion defining a cavity for receiving anend of an optical fiber, wherein the first portion has an free opticalpath that connects the cavity with a hole in the tip of the firstportion of the ferrule.
 32. The fiber optic connector of claim 31,wherein the diameter of the free optical path is substantially less thanthe diameter of the cavity.
 33. The fiber optic connector of claim 31,wherein a front end of the first portion of the ferrule is located at afocal point of the lens so that the lens will collimate the lightexiting the front end of the first portion of the ferrule.
 34. The fiberoptic connector of claim 25, wherein the alignment sleeve has asubstantially uniform outer diameter.
 35. A method of operating a fiberoptic jack that comprises a reflector, comprising: obtaining a firstfiber optic connector comprising: a first rigid elongate alignmentsleeve; a first collimating lens positioned behind the rear of the firstsleeve; and an end of a first optical fiber positioned behind the firstcollimating lens; inserting the first fiber optic connector into a firstport of the jack; obtaining a second fiber optic connector comprising: asecond rigid elongate alignment sleeve; a second collimating lenspositioned behind the rear of the second sleeve; and an end of a secondoptical fiber positioned behind the second collimating lens; insertingthe second fiber optic connector into a second port of the jack;injecting an optical signal into the jack using the first fiber opticconnector, wherein the optical signal is received by the secondcollimating lens and the second optical fiber after traveling throughthe second alignment sleeve; obtaining a third fiber optic connectorcomprising: a third rigid elongate alignment sleeve; a third collimatinglens positioned behind the rear of the third sleeve; and an end of athird optical fiber positioned behind the third collimating lens;inserting the third fiber optic connector fully into a third port of thejack, wherein the jack is configured such that in response to saidinsertion of the third fiber optic connector: (i) the reflector movesfrom a first position to a second position and (ii) the injected opticalsignal is received by the third collimating lens and the third opticalfiber, but not the second optical fiber; and removing the third fiberoptic connector from the jack, wherein the jack is configured such thatin response to said removal of the third connector: (i) the reflectormoves from the second position back to the first position and (ii) theinjected optical signal is received by the second collimating lens, butnot the third collimating lens.
 36. The method of claim 35, wherein thestep inserting the third fiber optic connector fully into the third portof the jack comprises inserting the third alignment sleeve into thethird port of the jack so that the tip of the alignment sleeve engages amechanism configured to move the reflector from the first position tothe second position.
 37. The method of claim 36, wherein the mechanismcomprises a wall of a moveable reflector housing that houses thereflector.
 38. The method of claim 37, wherein the wall is a slantedwall such that when the tip of the third alignment sleeve pressesagainst the wall the reflector housing moves away from a base of thejack.